Designing Topological Defect Lines Protected by Gauge-dependent Symmetry Indicators

TL;DR

This paper uses rotational symmetry indicators to design a topologically robust waveguide on a PCB, demonstrating reconfigurability and one-way termination, highlighting the importance of real-space gauge-dependent topological analysis.

Contribution

It introduces a novel design method for topological waveguides using symmetry indicators and real-space gauge dependence, verified experimentally on a PCB platform.

Findings

Successful experimental demonstration on PCB

Enhanced reconfigurability of the waveguide

Ability to form one-way terminations

Abstract

Symmetry indicators are a modern tool for characterizing topological phases that require only minimal computational expense but provide an elegant means of designing practical devices. This paper demonstrates how a rotational symmetry indicator can be used to construct and characterize a topologically robust waveguide, which is then verified experimentally on a printed circuit board (PCB) platform. The design takes advantage of the real-space gauge-dependency of the symmetry indicators and adopts a $C_6$ lattice with simple shifts, forming a defect line supporting topological edge modes. It is shown that the modes can realize the same features as previous topological waveguides, but in addition possesses a greater degree of reconfigurability and the unique ability to form a one-way termination. Moreover, the design illustrates the critical role real space information plays in determining the topological properties of photonic crystals, enabling a wider range of possible realizations.